记者从中国科学技术大学获悉：该校自旋磁共振实验室彭新华教授和江敏教授团队在《自然》杂志发表 最新研究成果，他们革新核自旋量子精密测量技术，成功搭建国际首个基于原子核自旋的量子传感网 络，让暗物质探测灵敏度实现质的飞跃。 研究人员表示，这一突破意味着，人类搜寻暗物质的"工具库"中，又新增了一款更精准的量子"捕手"。 本次研究不仅为暗物质探测开辟了新路径，其网络化、分布式探测思路，未来还可与引力波天文台协 同，用于搜寻更多宇宙奥秘。（记者李俊杰） ...

本文转自【人民日报】； 记者从中国科学技术大学获悉：该校自旋磁共振实验室彭新华教授和江敏教授团队在《自然》杂志发表 最新研究成果，他们革新核自旋量子精密测量技术，成功搭建国际首个基于原子核自旋的量子传感网 络，让暗物质探测灵敏度实现质的飞跃。 研究人员表示，这一突破意味着，人类搜寻暗物质的"工具库"中，又新增了一款更精准的量子"捕手"。 本次研究不仅为暗物质探测开辟了新路径，其网络化、分布式探测思路，未来还可与引力波天文台协 同，用于搜寻更多宇宙奥秘。 原标题：量子"捕手"为寻找暗物质提供新工具 ...

Core Insights - The research team from the University of Science and Technology of China has developed the world's first quantum sensing network based on atomic nuclear spins, significantly enhancing the sensitivity for dark matter detection, as published in the journal Nature [1][2] Group 1: Quantum Sensing Technology - The quantum sensors are equipped with two key innovations: storing fleeting signals in a nuclear spin coherence state for nearly a minute, which greatly extends the detection window, and a self-developed quantum amplification technology that enhances weak signals by 100 times [1] - The team has successfully deployed five ultra-sensitive quantum sensors in Hefei and Hangzhou, creating a distributed detection network synchronized by satellite time [2] Group 2: Dark Matter Detection - The research has provided the most stringent limits on dark matter models across a wide range of axion masses, with some precision limits exceeding astronomical observations by 40 times [2] - This breakthrough adds a more precise "quantum tool" to humanity's toolkit for searching dark matter, with potential future enhancements in sensitivity by four orders of magnitude through global networking and space deployment [2]

Core Insights - The research team from the University of Science and Technology of China has developed the world's first quantum sensing network based on atomic nuclear spins, significantly enhancing the sensitivity for dark matter detection [1][3] - Dark matter, which constitutes approximately 26.8% of the universe, interacts through gravity but not electromagnetically, making it challenging to detect [1] - The team has established a distributed detection network using five ultra-sensitive quantum sensors, achieving detection precision that surpasses astronomical observations by 40 times in certain mass ranges of axions, a leading candidate for dark matter [3] Group 1 - The quantum sensors are equipped with advanced features that allow for the storage of fleeting signals in a nuclear spin coherence state for nearly a minute, greatly extending the detection window [1] - The team has developed a self-research quantum amplification technology that enhances weak signals by a factor of 100, making it easier to detect subtle interactions [1] - The breakthrough adds a new, more precise tool to humanity's arsenal for searching for dark matter, with potential future enhancements in sensitivity through global networking and space deployment [3] Group 2 - The sensors are deployed in Hefei and Hangzhou, synchronized via satellite for precise timing, forming a distributed detection network [3] - After two months of continuous observation, the team has provided the strictest constraints on dark matter models across a wide range of axion masses [3] - Future collaborations with gravitational wave observatories could further increase detection sensitivity by four orders of magnitude [3]

Core Viewpoint - The research team from the University of Science and Technology of China has developed the world's first quantum sensing network based on atomic nuclear spins, significantly enhancing the sensitivity for dark matter detection and providing a new pathway to unravel this cosmic mystery [1][2]. Group 1: Quantum Sensing Technology - The team has innovatively equipped quantum sensors with two key enhancements: storing fleeting signals in a nuclear spin coherence state for nearly a minute, which greatly extends the detection window [1] - They also developed a quantum amplification technology that increases weak signals by 100 times, making it easier to detect subtle interactions [1]. Group 2: Dark Matter Detection - The research team deployed five ultra-sensitive quantum sensors in Hefei and Hangzhou, synchronizing them via satellite to create a distributed detection network [2] - After two months of observation, the team established the most stringent limits on dark matter models across a wide range of axion masses, achieving precision 40 times greater than results obtained from supernova observations [2]. Group 3: Future Implications - This breakthrough adds a more precise "quantum tool" to humanity's toolkit for searching dark matter, with potential future enhancements in sensitivity by four orders of magnitude through global networking and space deployment [2].

Core Insights - The research team from the University of Science and Technology of China has developed the world's first quantum sensing network based on atomic nuclear spins, significantly enhancing the sensitivity for dark matter detection [1][2] - Dark matter constitutes approximately 26.8% of the universe's total mass, yet it does not emit light or interact electromagnetically with ordinary matter, making it a critical component of the universe's structure [1] - The study introduces a new quantum sensor technology that can store fleeting signals for nearly a minute and amplify weak signals by 100 times, improving the chances of detecting dark matter interactions [1][2] Group 1 - The quantum sensing network connects Hefei and Hangzhou, utilizing satellite synchronization for precise time correlation, which enhances the reliability of detection results by filtering out noise [2] - Although the team did not capture a clear signal of the "dark matter wall," they established stringent limits on dark matter models across a wide range of axion masses, achieving a precision 40 times greater than astronomical observations using supernovae [2] Group 2 - This breakthrough adds a more precise "quantum tool" to humanity's arsenal for dark matter detection, paving the way for future collaborations with gravitational wave observatories to explore more cosmic mysteries [4] - The research team plans to expand the quantum detection network's coverage through global networking and space deployment to further enhance dark matter detection sensitivity [4]